Regional study led by Texas A&M professor was first of its kind and produced alarming results.

Apr 21, 2020

Daily street life in the early morning during extreme smog conditions, in New Delhi, India in 2012. (Photo courtesy of iStock/Getty.)

Scientists know that extreme heat has a negative impact on the human body — causing distress in the respiratory and cardiovascular systems — and they know that extreme air pollution can also have serious impacts on the human body.

But as climate change impacts continue globally, how often will humans be threatened by both of those extremes when they occur simultaneously?

“South Asia is a hot-spot for future climate change impacts,” said Dr. Yangyang Xu, an assistant professor in the Department of Atmospheric Sciences, in the College of Geosciences at Texas A&M. Extreme heat occurrences worldwide have increased in recent decades, and at the same time, many cities are facing severe air pollution problems, featuring episodes of high particulate matter (PM) pollution, he said. This study provides an integrated assessment of human exposure to rare days of both extreme heat and high PM levels.

“Our assessment projects that occurrences of heat extremes will increase in frequency by 75% by 2050, that is an increase from 45 days a year to 78 days in a year. More concerning is the rare joint events of both extreme heat and extreme PM will increase in frequency by 175% by 2050,” Xu said.

“Climate change is not just a global average number, it is something you can feel in your neighborhood,” he said, and that’s why regional-scale climate studies are important.

The study’s regional focus was South Asia: Afghanistan, Bangladesh, Bhutan, India, Myanmar, Nepal, and Pakistan. The scientists used a high-resolution, decadal-long model simulation, using a state-of-the-science regional chemistry-climate model.

Xu lead the first of its kind research project, and scientists from the National Center for Atmospheric Research (NCAR) in Boulder, Colorado, led the development of the fully coupled chemistry-climate model and performed model simulations for the present-day and future conditions.

“These models allow chemistry and climate to affect each other at every time step,” said Dr. Rajesh Kumar, a project scientist at NCAR and co-author on the study.

Mumbai, Maharashtra, India - October 2019: High air pollution and haze envelops the high rises in the suburb of Kandivali East. (Photo courtesy of iStock/Getty.)

Dr. Yangyang Xu.

As climate change impacts continue to become reality, it is important for scientists to consider human impacts of multiple extreme conditions happening simultaneously, Xu said. Projected increases in humidity and temperature are expected to cause extreme heat stress for the people of South Asia, where the population is projected to increase from 1.5 billion people to 2 billion by 2050.

“It is important to extend this analysis on the co-variability of heat and haze extremes in other regions of the world, such as the industrial regions of the U.S., Europe, and East Asia,” Barth said.

The analysis also showed that the fraction of land exposed to prolonged dual-extreme days increases by more than tenfold in 2050, much larger than the increase when assessed individually.

“I think this study raises a lot of important concerns, and much more research is needed over other parts of the world on these compounded extremes, the risks they pose, and their potential human health effects,” Xu said.